KINETICS OF THERMALLY INACTIVATED UREASES AND MANAGEMENT OF
SAND PRODUCTION THROUGH UREOLYSIS-INDUCED MINERAL
PRECIPITATION
by
Vincent John Morasko
A thesis submitted in partial fulfillment of the requirements for the degree
of
Master of Science
in
Chemical Engineering
MONTANA STATE UNIVERSITY Bozeman, Montana
July 2018
©COPYRIGHT
by
Vincent John Morasko
2018
All Rights Reserved
ii
ACKNOWLEDGEMENTS
This project was made possible through funding from the Department of Energy’s
project, Wellbore Leakage Mitigation Using Advanced Mineral Precipitation Strategies
(DE-FE0026513). Thank you to my graduate committee, Dr. Robin Gerlach, Dr.
Adrienne Phillips, and Dr. Jeff Heys. Without your support, advice, and belief in me, I
could not have succeeded. Special thank you to Dr. Marnie Feder, Joe Eldring, Abby
Thane, and the rest of the Bioprocess lab group of 2016-2018 for teaching me laboratory
techniques and helping make these projects a success, as well as Neerja Zambare for
being patient with me and taking some stunning microscopy images. Thank you to
everyone at the Center for Biofilm Engineering for sustaining and continuing to build
such a great environment to learn, work, and create lasting friendships. I would like to
acknowledge our late Warren Jones for providing me with advising during my
undergraduate years at Montana State University. His words of wisdom guided me to
finding a career that suited my passion, ultimately returning to Montana State University
to further my education. Thank you, Warren. You are missed and most certainly not
forgotten.
iii
TABLE OF CONTENTS
1. INTRODUCTION ...........................................................................................................1
Background ......................................................................................................................1 Thesis Overview ..............................................................................................................2
2. A STUDY ON INACTIVATION AND CATALYSIS RATES OF PLANT SOURCED UREASE AT ELEVATED TEMPERATURES .........................................5
Abstract ............................................................................................................................5 Introduction ......................................................................................................................6 Materials & Methods .....................................................................................................10
Materials ................................................................................................................10 Batch Kinetic & Inactivation Experiments ...........................................................10 Modeling Methods .................................................................................................12
Results & Discussion ....................................................................................................15 Ureolysis Rates & Temperature Dependency .......................................................15 Temperature-Dependent Kinetics of Urea Hydrolysis by Jack Bean Meal ...........17 Conclusions ............................................................................................................22 List of Terms ..........................................................................................................24
3. A LABORATORY STUDY TO REDUCE PRODUCED SAND IN PRODUCTION OIL AND GAS WELLS USING CALCIUM CARBONATE PRECIPITATION ...............................................................................25
Literature Review ...........................................................................................................25 Materials & Methods .....................................................................................................31
Reactor Design & Configuration ..........................................................................31 Media & Injection Fluids ......................................................................................34
Operations Strategy .......................................................................................................35 Proppant Loading ..................................................................................................35 Microbial Inoculum Preparation ...........................................................................37 Mineralization Fluid Injection ..............................................................................37 Production Flow .....................................................................................................39 Fluid Sampling .......................................................................................................41 Jung Urea Assay ....................................................................................................41 Calcium Assay .......................................................................................................42 Cell Population Analysis........................................................................................42 Imaging ..................................................................................................................43
Results & Discussion ..................................................................................................43 Fluid Sample Analysis ..........................................................................................43 pH Analysis ...........................................................................................................46
iv
TABLE OF CONTENTS CONTINUED
Viable Cell Counts .................................................................................................48 Flow Rate Reduction..............................................................................................48 Produced Sand Collected .......................................................................................49 Sand Production within the Microbial & Enzymatic Experiments ........................51 Reactor Sampling & Mineralized Sand Observations ...........................................52 Post Experiment Imaging .......................................................................................55 Conclusions ............................................................................................................59
4. CONCLUSIONS & SUGGESTIONS FOR FUTURE WORK ....................................61
Suggestions for Future Work .................................................................................62
REFERENCES .................................................................................................................64 APPENDIX: Supplemental Information for Chapter 2 .....................................................72
v
LIST OF TABLES
Tables Page
2.1. Graphical representation of inactivation models and their corresponding Theoretical inactivation pathway(s) investigated within this study ................13
2.2. Temperature dependent equations and correlation values (R2)
of kinetic coefficients obtained for first-order, series-parallel and series-type models ............................................................22
3.1. Analog Reactor Experiment Media Recipes (Stock Solutions) ......................35
3.2. Media recipe to make 1x concentration Phosphate Buffer Solution ..............43
3.3. Effluent of flow data representing key points during the control 111111111 and mineralization portions of the analog reactor experiment .......................50 3.4. Mass of proppant sand collected in the pan for control experiment 1-3 and statistical analysis (mass of sand in the inner pipe was not quantified) .........51 3.5. Mass of proppant sand produced from the Microbial and enzymatic experiments ...........................................................53
A1. Summary of conductivity correlation equations .............................................74
A2. Summary of enzyme activities and ureolysis rates for plant-based sources ...........................................................77
A3. Summary of first-order inactivation constants and half-life for 20-80°C .................................................................................78
A4. Kinetic model coefficients for first-order, series-parallel, and series type models ............................................................79
vi
LIST OF FIGURES
Figures Page
2.1. Urea concentrations (g*L-1) over time (minutes) ............................................18
2.2. Residual activity of jack bean meal urease exposed to various temperatures ...................................................................................19
2.3. Predicted fit for series-type (solid line), series-parallel (long dashes), and first-order (dotted) models compared to experimental ureolysis data .....20
3.1. Different methods/materials used to reduce produced sand ...........................26
3.2. Reactor configuration used by Fleming et al (2012) and Bansal et al. (2014) ..................................................................................30 3.3. Typical horizontal oil well with fractures .......................................................32 3.4. Computerized drawing of the sand packed analog reactor (without sand) created in SolidWorks® ...................................................................................32 3.5. Perforation gun (left) and helical perforation pipe (right) ..............................33 3.6. Uniform proppant sand (left) vs. non-uniform sand (right) ............................34 3.7. Proppant sand loading configuration .............................................................36 3.8. Mineralization flow phase ...............................................................................38 3.9. Flow schematic of mineralization flow phase ...............................................38 3.10. Flowback or production phase ........................................................................40 3.11. Percentage of urea hydrolyzed for the microbial and enzymatic Experiments vs. Number of YE+ pulses ..........................................................44 3.12. Calcium removed (shown as a percent) for the microbial and enzymatic experiments vs. Number of YE+ pulses .................45 3.13. pH vs. Number of YE+ Pulses for the Microbial Experiment ........................47 3.14. pH vs. Number of YE+ Pulses for the Enzymatic Experiment.......................47
vii
LIST OF FIGURES CONTINUED
Figures Page 3.15. Control experiment reactor imaging and proppant sand collection (typical) ..................................................................................51 3.16. Mineralized sand pack from the microbial (left) and enzymatic (right) experiments ..................................................................55 3.17. Mineralized samples pack from the microbial (left) and enzymatic reactors near the inner pipe .....................................................55 3.18. Detailed photos of the calcified tunnel ...........................................................56 3.19. Stereoscope image of mineralized tunnel from the microbial experiment .....57 3.20. Stereoscope image of sand obtained from the enzymatic experiment samples .......................................................................58 3.21. Field Emission Scanning Electron Microscope image of potential calcium carbonate precipitation occurring on sand obtained from the enzymatic experiment samples .......................................................................58 3.22. Two proppant sand particles bonded together by two calcium carbonate precipitate masses .....................................................59
A1. Temperature dependent inactivation coefficient ...........................................75
A2. Apparent first-order rate coefficients for various urease sources .................76
A3. Residual ureolytic activity of jack bean meal after exposure to temperatures Between 50 and 80°C ...............................................................78
A4. Temperature dependent inactivation coefficient for Series inactivation determined by plotting k1 values obtained from inactivation experiments across the temperature range of 50-80°C. ......................................................79
A.5. Temperature dependent inactivation coefficient for Series inactivation determined by plotting k2 values obtained from inactivation experiments across the temperature range of 50-80°C. .....................................................80
viii
LIST OF FIGURES CONTINUED Figures Page
A.6. Temperature dependent inactivation coefficient for Series inactivation determined by plotting β values obtained from inactivation experiments across the temperature range of 50-80°C. .....................................................80
A7. Temperature dependent inactivation coefficient for Series-parallel inactivation determined by plotting k1 values obtained from
inactivation experiments across the temperature range of 50-80°C. ............81 A8. Temperature dependent inactivation coefficient for Series-parallel inactivation determined by plotting k2 values obtained from inactivation experiments across the temperature range of 50-80°C. .............81
A9. Temperature dependent inactivation coefficient for Series-parallel inactivation determined by plotting k3 values obtained from inactivation experiments across the temperature range of 50-80°C ...............82
A10. Temperature dependent inactivation coefficient for Series-parallel inactivation determined by plotting β values obtained from inactivation experiments across the temperature range of 50-80°C ...............82
ix
ABSTRACT
Biocement has the potential to seal subsurface hydraulic fractures, manipulate subsurface flow paths to enhance oil recovery, treat fractured cement, stabilize soil structures and minimize dust dispersal. Biocement can be formed using the urease enzyme from various sources (bacteria, plant, or fungi) to break down urea into carbonate, combining with calcium for use in engineering applications such as biocement production. Higher temperatures, pressures, and extreme pH conditions may be encountered as these engineering applications expand deeper into the subsurface. Temperatures beyond 1000 meters can exceed 80°C, potentially rapidly inactivating the enzyme. The first part of this study focused on monitoring urea hydrolysis catalyzed by jack bean urease at temperatures ranging from 20-80°C. An increasing rate of urease inactivation was observed with increasing temperatures and first-order models described the kinetics of urea hydrolysis and enzyme inactivation properly.
The second part of this study focused on developing a technology to mitigate sand transport in oil and gas wells. This study addressed a method to cement sand in the subsurface so that it is not returned when oil or gas is extracted. As the sand leaves the formation, it can cause damage in the subsurface, leading to economic concerns, as well as reducing the lifespan of pumps, piping and other components on the well pad. A reactor system was developed to mimic a subsurface oil well that produces sand. Biocement production was promoted within the reactor, utilizing common sources of urease (Sporosarcina pasteurii and Canavalia ensiformis or jack bean meal). The resultant calcium carbonate/sand mass was subjected to elevated flowrates, simulating field conditions where sand is potentially fluidized and potentially transported into the wellbore. It was shown that biocement can reduce sand transport while allowing for higher flow rates than conditions without biocement.
The findings from this study broaden the potential application range of biocementation technologies into higher temperature environments. Applying biocement specifically to sand mitigation may have significant environmental, economic, and safety implications within the natural resource industry.
1
CHAPTER ONE
INTRODUCTION
Background
This thesis describes two studies: (1) it explores temperature-dependent kinetics
of plant sourced urease enzymes and (2) a potential application of urease from microbe
and plant sources to induce calcium carbonate precipitation to prevent sand from being
transported into an oil-producing wellbore.
Urea hydrolysis-induced calcium carbonate precipitation (sometimes called
biocementation) is a natural process catalyzed by enzymes (either from bacteria, plants,
or fungi). 1-4 Calcium carbonate precipitation has the potential to make positive impacts
to environmental and chemical engineering applications. Previous works have proposed
the use of carbonate precipitation to restrict fluid flow to mitigate escaping greenhouse
gasses in carbon sequestration and recently have been applied to improve the injection
pressure of an aged well (data not shown). 5-9
Calcium carbonate precipitates can be formed by at least three mechanisms;
microbially induced calcium carbonate precipitation (MICP), enzyme induced calcite
precipitation (EICP), and thermally induced calcium carbonate precipitation (TICP). For
TICP to occur, urea spontaneously hydrolyzes without the aid of an enzyme, presumably
due to sufficiently high temperatures. TICP was not considered in this work, such that the
focus of this thesis will be MICP and EICP. The MICP and EICP mechanism both utilize
the urease enzyme to hydrolyze urea into ammonia (NH3) and carbonic acid (H2CO3)
2 (Equation. 1.1-1.2). The carbonic acid is converted into carbonate (CO3
2-) through a
series of acid base reactions within the system (Equation. 1.3-1.5). Once formed, the
carbonate and calcium combine to precipitate calcium carbonate (CaCO3) (Equation
1.6).10
Equation. 1.1
→ Equation. 1.2
↔ Equation. 1.3
2 2 ↔ 2 2 Equation. 1.4
2 ↔ 2 Equation. 1.5
↔ Equation. 1.6
Thesis Overview
In this thesis, two topics are covered, one exploring the potential to advance
biocement applications into a broader temperature range and the other, developing a
novel analog reactor to simulate a potential mineralization application. Chapter 2 is
comprised of a manuscript “A study on inactivation and catalysis rates of plant sourced
ureases at elevated temperatures”, which will be submitted to Environmental Science and
Technology. Increasing temperatures are usually encountered with increasing depths in
the subsurface. The Phillips/Gerlach laboratories at Montana State University (MSU)
demonstrated that most, if not all, of the urease from urease-producing bacteria tested in
the laboratory grown above 44°C were inactivated due to long term elevated temperature
exposure. Hence, plant-sourced enzymes were used in this study to investigate a potential
alternative urease source to extend the temperature range for subsurface applications. The
3 use of enzymes also eliminates the need for introducing potentially non-native bacterial
species into the environment.
The study presented in Chapter 2 developed a thermal inactivation model,
describing the rate of thermal inactivation of the urease enzyme from the plant Canavalia
ensiformis (jack bean meal). Three different models were investigated to find the most
computationally simple model compared to properly describe experimental urea
hydrolysis data. The inactivation model developed is being used in a reactive transport
model developed with collaborators at the University of Stuttgart. 11, 12
Chapter 3 describes an analog sand packed reactor, intended to mimic a horizontal
oil and gas well, a common orientation in the modern oil field. This chapter addresses an
expensive field issue referred to in the oil and gas industry as ‘produced sand’. Produced
sand is either native (from existing geology in the subsurface) or non-native sand
(proppant, often added to the well to hold open hydraulic fractures). This sand can be
unintentionally transported into the wellbore during oil and gas extraction and cause
damage. Hence, a wellbore analog reactor, representing the space between the well bore
and the formation, was filled with 40/70 proppant sand (commonly used in hydraulically
fractured oil and gas wells). Biocement formation was induced in two separate
experiments, each using a different urease source (microbial and plant-based sources).
The biocement’s ability to hold the sand in place during field-like flow condition within
the reactor was tested, comparing the mass of sand that transported during the high fluid
flows. These experiments showed that biocement could potentially reduce the amount of
produced sand compared to control experiments while still achieving a relatively high
4 flow rate (for a laboratory experiment) through the biocemented sand pack. Finally,
chapter 4 summarizes the results of chapters 2 and 3 and outlines some recommendations
for potential future work.
5
CHAPTER TWO
A STUDY ON INACTIVATION AND CATALYSIS RATES OF PLANT SOURCED
UREASE AT ELEVATED TEMPERATURES
Abstract
Engineered (bio)mineralization, which involves the use of the urease enzyme to
catalyze the hydrolysis of urea to promote carbonate mineral precipitation, has been
shown to be a promising technique for use in subsurface and remediation applications.
The current study investigates the use of plant-based ureases under a range of
temperatures that are typically found in the near and deeper subsurface. Batch
experiments revealed that jack bean meal demonstrated a 4-34 times higher activity (2.46
µmol urea hydrolyzed/mg ground jack bean meal/minute) than the other tested ground
plant-based urease preparations (from soybean, pigeon pea and cottonseed). Ureolysis
rates and enzyme inactivation at temperatures between 20 and 80°C were evaluated for
jack bean meal. The first-order ureolysis rate coefficients ranged from 0.0019 kurea (min-1)
at 20° C to 0.0335 kurea (min-1) at 80°C, increasing with temperature. Jack bean urease
became >97% inactivated in as little as 0.5 hours at 80°C and in as long as 168 hours at
50°C. A simple first-order inactivation model was deemed sufficient, among the three
tested enzyme inactivation models (first-order, series-parallel and series-type), to
describe the inactivation of urease appropriately over the investigated range of
temperatures (correlation coefficients were between 0.86 and 0.99). The developed
6 enzyme kinetics and inactivation model provides a fairly simple mathematical
relationship that can be used in reactive transport models.
Introduction
Engineered (bio)mineralization or ureolysis-induced calcium carbonate
precipitation (UICP) techniques has been an increasingly popular area of research for use
in subsurface and remediation applications.6, 13, 14 UICP is a process catalyzed by enzymes
(either from bacteria, plants, or fungi), during which urea is hydrolyzed for use in calcium
carbonate precipitation. 1-4 Engineered mineralization has the potential to be utilized in
place of traditional cement or grout in the subsurface for remediating wellbore integrity,
sealing fractures in concrete and rock formations utilized for fluid storage (e.g. CO2, natural
gas, or H2), controlling flow paths for oil and gas recovery, or creating subsurface barriers
for water pollution control.15-18 The application of (UICP) might be governed by
regulations limiting the amendment of subsurface environments with living microbes or by
temperature conditions inhibitory to microbial growth. To overcome challenges of working
with living microbes, this work evaluates the use of ureases from plant-based sources as an
alternative.
Biologically induced mineralization techniques utilizing the ureolytic bacterium
Sporosarcina pasteurii to induce calcium carbonate (CaCO3) precipitation have been
extensively researched.1, 5, 7, 19-22 In the presence of urea, the urease enzyme in S. pasteurii
catalyzes the hydrolysis of urea, altering the chemical environment towards favorable
conditions for precipitation of CaCO3 in the presence of calcium (Equation 2.1).
7
(NH2)2CO + 2H2O + Ca2+ → 2NH4+ + CaCO3 Equation 2.1
Ureolysis-driven CaCO3 biomineralization has been successfully implemented in
large scale field applications.15, 23, 24 The demonstration reported by Phillips et al. (2016)
showed the potential for MICP to seal a subsurface fracture at approximately 340 m depth.
In that study, the subsurface fluid temperature was around 20°C, i.e. within the range for
microbial growth though microbial growth was not evaluated.25 Temperature generally
increases with increasing depth in the terrestrial subsurface, and to extend the application
range more temperature-tolerant strategies need to be developed. Furthermore, increased
pressures and harsher chemical environments, such as CO2 saturated brines, may further
limit the suitability of microbes.
While urease is present in bacteria and whole cell ureolysis rates have been
investigated e.g. by Lauchnor et al. (2015), there are also numerous other eukaryotic
sources of the enzyme.26-28 Active plant sources of urease include jack beans (Canavalia
ensiformis), soybeans (Glycine max), cottonseeds (Gossypium hirsutum) and pigeon peas
(Cajanus cajan).28 The urease enzyme within the mentioned plants is used as a method to
gather nitrogen for growth and in some cases, has been speculated to create an insecticide
during germination but this has not been confirmed.29 Ureases from plants have been
isolated and concentrated and could provide a potential strategy for implementing UICP in
engineering applications. 30-38
Utilizing purified urease (Enzyme Commission (EC) number 3.5.1.5) from jack
bean, Nemanti et al. (2003) demonstrated that the enzymatically catalyzed hydrolysis of
urea can lead to the formation of calcium carbonate. Nemati et al. (2003) observed a 98%
8 reduction of the permeability in porous media and found that by increasing the temperature,
the rate of CaCO3 precipitation could be enhanced.39 Handley-Sidhu et al. (2013) also
observed a 98% reduction of the permeability in porous media but found that 91.5% of the
calcium carbonate precipitated was within the initial column section.38
The activity of purified urease has been reported to be in the range of 2700 – 3500
units per g of meal (µmol of urea hydrolyzed per minute per gram of meal).28 Utilizing jack
bean meal (JBM), Handley-Sidhu et al. (2013) determined the ureolytic activity at 10°C to
be 3130 ± 160 units, which is comparable with these observations since jack beans have
been reported to contain between 0.07-0.14% urease/dry mass.40 Ureolysis rates are
typically reported in the form of rate constants (such as kurea, first-order rate constant) and
were determined to be between 3.47x10-5 and 1.88x10-4 [min-1] (0.05 and 0.27 [day-1]) for
0.13-0.50 g*L-1 of JBM.38
Inactivation mechanisms for a variety of enzymes have been researched.41-43 For
instance, Polakovic et al. (1996) summarized a large number of mechanisms involved in
the inactivation of enzymes, and examined the activity-time profiles of four mathematical
forms ranging from first-order to higher order biphasic models.44 Due to many different
possible pathways of enzyme inactivation, it is difficult to fully determine the mechanisms
responsible for inactivation, though an adequate fit of the applied model is often accepted
as an explanation for the mechanisms involved.45 For urease in particular, Illeova et al.
(2003) proposed a thermal inactivation model that predicted thermal inactivation for
purified urease between the temperatures of 55 and 87.5°C using a biexponential model,
with at least three different reaction steps, including reversibility.46 Henley and Sadana
9 (1984) and Sadana (1991) stated that often a first-order model adequately describes
inactivation kinetics for broad temperature ranges despite the potential complexity of the
enzyme structure and the inactivation mechanisms.
This study aimed to determine the ureolysis and inactivation rates (occurring in the
range of 20-80°C) for the urease enzyme from ground extracts of various plant-based
sources. To meet these objectives, ground plant-based sources of the enzyme were
combined with urea at different temperatures in batch systems to determine urea hydrolysis
and enzyme inactivation rates. Then, appropriate inactivation models were applied and
compared with the results of the experimental data. The temperatures examined in this
study are in the range of 20-80°C, where the higher temperatures are typical of deeper
subsurface applications (more than 1000 m below ground surface). The motivation for this
work was to determine the thermal inactivation effects in a temperature range where UICP
could be applied in the deeper subsurface. The importance of studying the temperature-
dependent ureolysis and inactivation kinetics is also to inform reactive transport models to
be used for predicting calcium carbonate placement.11, 12, 47
10
Materials & Methods Materials
Jack bean meal (JBM) with an activity specified as ≥ 1500 units/gram (J0125,
Sigma-Aldrich, St. Louis, MO) was utilized as a source of urease in all kinetic and
inactivation experiments (one enzyme unit will liberate 1.0 micromole of ammonia from
urea per minute per gram of meal at pH 7 and 25°C). Other plant-based sources of ground
urease were: soybean flour (SB) (S9633, Sigma-Aldrich, St. Louis, MO), cottonseed flour
(CS) (C4898, Sigma-Aldrich, St. Louis, MO) and pigeon peas (PP) (North Bay Trading
Co. Brule, WI), ground to a flour using a household coffee grinder. All urease sources were
prepared as 5 g*L-1 suspensions on a stir-plate and mixed at 300 rpm for approximately 16
hours. ACS certified urea (Fisher Scientific, Fair Lawn, NJ) was prepared as a 40 g*L-1
solution. All solutions were made with deionized water (DI) and filtered through 0.2 µm
disposable Nalgene bottle top filters (ThermoFisher, Rochester, New York) prior to use.
Glassware was autoclaved (121°C) prior to use.
Batch Kinetic & Inactivation Experiments
Batch experiments were carried out in digital shaking water baths operating at the
desired experimental temperature (20-80°C) at 70 rpm. The initial heating period to reach
each temperature was determined by measuring the temperature over time with an Omega
CDS107 temperature probe. Time to reach 95% of the target temperature was determined
to be less than 3.5 minutes for each treatment. Experiments were carried out in 30 mL glass
bottles that contained 10 mL of 5 g*L-1 filtered ground plant-based urease (JBM, SB, CS,
11 or PP) to which 10 mL of 40 g*L-1 pre-heated urea solution was added once the
experimental temperature was reached. This created a urease-urea mixture with final
concentrations of 2.5 g*L-1 JBM, SB, CS or PP and 20 g*L-1 urea.
Batch experiments were run in triplicate for durations of two to eight hours,
depending on temperature, while measuring conductivity with an Omega CDS107
conductivity probe. In addition, 2*60 µL samples were taken for urea concentration
analysis (as presented in Phillips 2013, modified from Jung et al. (1975)) every 15 minutes
up to two hours and then every 30 minutes up to eight hours. In all batch experiments, less
than 10% of the total experimental volume was taken for sampling. As a positive control,
treatments were also run at 30°C to monitor potential variation between the different
enzyme preparations. A urease-free control with 20 g*L-1 urea was run to assess abiotic
hydrolysis within the experimental time; abiotic hydrolysis of urea was not observed.
Both a direct urea assay and conductivity-based measurements were used to
monitor the rate of urea hydrolysis. A modified method of the colorimetric Jung Assay was
performed in 96 well plates with absorbance measured at 505 nm to assess urea
concentrations.3, 48 Data were correlated to conductivity readings taken in parallel at each
temperature. The conductivity method can be used to measure the proportional increase in
conductivity due to the conversion of non-ionic urea into ionic ammonium and
(bi)carbonate ions during urea hydrolysis.19 The equation of the resulting correlation line
of the combined triplicates was used to convert the conductivity measurements to urea
hydrolyzed (g*L-1). This Jung Assay-conductivity correlation can be found in the
Appendix as Table A1.
12
Inactivation experiments were performed by exposing 10 mL samples of JBM
suspensions to elevated temperatures between 50 and 80°C over a range of exposure times
between 0.5 and 168 hours. Exposed JBM samples were cooled down rapidly on ice and
stored at 4°C until utilized in batch experiments. Each 10 mL sample of thermally-exposed
JBM urease was heated to 30°C and mixed with 10 mL of a 40 g*L-1 urea solution at 30°C
to determine the average urea hydrolysis rate, or enzyme activity (A). This was determined
by finding the difference in the initial and residual urea concentrations after the thermally
exposed JBM batch studies and dividing by the duration (Equation 2.2). Here, U0 and UΔt
are the urea concentrations initially and after two hours (120 minutes), and Δt is the time
of the kinetic experiment (2 hours).
∆ Equation 2.2
Modeling Methods
Urea hydrolysis promoted by ground plant-based enzyme sources has been shown
to follow a first order rate expression suggested by Ferris et al. (2003) in Equation 2.3 and
summarized by Handley-Sidhu et al. (2013) for urea concentrations near 20 g*L-1.38, 49
Initial comparisons were based on the first order rate coefficients (kurea) determined from
120 minute batch studies for each temperature, calculated using the hydrolysis rates from
experimental data (Equation 2.3).
Equation 2.3
Where dU is the differential change in urea concentration, dt is the differential
change in time and kurea is the apparent first order reaction rate coefficient (min-1).
13
Upon inspection of the data, it was found that urease from all plant-based sources
were inactivated at elevated temperatures, 50°C being the first temperature that significant
inactivation was observed. The model was modified to consider both changes in urea
concentration (U) and enzyme activity (A) (Equation 2.4) where A and kurea were
temperature dependent variables.
Equation 2.4
Here, the reaction equation is second order overall, first-order with respect to urea
concentration (U) and first-order with respect to enzyme activity (A). The inactivation of
the urease enzyme at elevated temperatures is influenced by the activity term (A), a
function of temperature within this study. Three inactivation models of differing
complexity were considered, a single step and two biphasic inactivation models. These
evaluated models are graphically shown in Table 2.1.
Table 2.1. Graphical representation of inactivation models and their corresponding theoretical inactivation pathway(s) investigated within this study.
Literature suggested that enzyme inactivation kinetics can be described adequately
using a first-order inactivation model (Equation 2.5), which describes a one-step
irreversible inactivation of the enzyme from its native form to an inactivated form. 42, 45, 46,
Model Mechanism
First order
Series‐parallel
Series‐type
→
→ →
14 50 In some cases, a first-order model may describe an enzyme’s inactivation mathematically
but may not be exact from a mechanistic standpoint. In these cases, a higher order or a
more complex inactivation model might describe the pathway more realistically. More
complicated enzyme inactivation models have been identified in the literature including a
series-parallel and series type model.51 One activity model (Equation 2.6) describes a
series-parallel inactivation scheme, in which the native enzyme follows one of two paths
towards the inactivated form, a two-step series path that assumes a partially inactivated
isozyme during inactivation and a single step path toward complete inactivation. The other
higher order activity model (Equation 2.7) similar to the series-parallel but without the
second path for complete inactivation. In each of these higher order models, kinetic
coefficients k1, k2 and k3 are the rates of enzyme inactivation from the native form (E) to
the isozyme form (EI) to the inactive form (Ed) (see Table 2.1 for a graphical
representation). The β value is an activity ratio of E and EI. (While details are provided
here for the direct inactivation model, detailed explanations of the higher order inactivation
mechanisms can be found in the Appendix)
∗ Equation 2.5
1 Equation 2.6
1 Equation 2.7
The single step inactivation model was the simplest model invested within this
study (Equation 2.5). Where Ao is the initial activity of the enzyme (assumed to be 1), A is
15 the activity after exposure to elevated temperatures for time, t and kd(T) was the first-order
thermal inactivation rate coefficient at the given temperature (T).
The inactivation rate coefficients (kd(T)) for temperatures between 50 and 80°C
were determined by linearly regressing the residual activity versus time on a semi-log plot,
with the slope being kd(T). The resulting kd values were plotted against temperature to
obtain a temperature-dependent inactivation coefficient through exponential regression,
resulting in an exponential type plot (Figure A.1) (Equation 2.8).
∗ ∗ Equation 2.8
Where T is temperature, P is the pre-exponential factor, Ea is the inactivation energy and
R is the universal gas constant per the Arrhenius equation.
When analyzing the enzyme inactivation mechanisms, the parameters associated
with the series-parallel and series inactivation models were estimated using a nonlinear
least squares regression code within MATLAB® called ‘fmincon’. The main function of
‘fmincon’ was to minimize the difference between experimental and predicted data by
varying the inactivation coefficients for the inactivation scheme investigated. Constraints
were added that would only evaluate a specific range of numerical values.
Results & Discussion
Ureolysis Rates & Temperature Dependency
The rates of ureolysis in batch experiments between the four plant sources were
compared based on their apparent first-order rate coefficients (not accounting for
inactivation) and their respective activities at 30°C and 60°C for JBM, SB, PP and CS
16 (Equation 2.3) (Figure A.2). It was observed that JBM exhibited 2.1 times higher ureolysis
rates at 30°C and 3.1 times higher at 60°C than the second most active ureolytic source
(within this study), SB for both temperatures (Table A.2). Ureolysis rates have been
reported for temperatures between 10 – 30°C as 0.4 – 0.60 [day-1] (2.78x10-4 – 4.16x10-4
[min-1]) for 1.0 g*L-1 ground jack bean meal and 0.04 – 2.29 [day-1] (2.78x10-5 – 1.59x10-
3 [min-1]) for microbial cultures with optical densities (OD600nm) between 0.015 and
0.14from other literature sources.16, 38, 49, 52, 53 The first-order urea hydrolysis rate
coefficients reported here are determined from data obtained over the first hour of ureolysis
in the presence of 2.5 g*L-1 of JBM, SB, PP or CS, normalized to 1 g*L-1. The first-order
ureolysis rates were determined to be between 1.11 and1.93x101 [(g*day)-1] (7.74x10-4 and
1.34x10-2 [(g*min)-1]) (Table A.2).
Each plant-based urease source was mixed to the same mass concentration of meal
to compare the concentration of urea hydrolyzed per time. It must be noted that the levels
of active urease in the different plant sources was unknown. The urease activities
determined from these experiments decreased in the order of JBM > SB > PP > CS. At
30°C JBM was the most active with 970 units (µmol of urea hydrolyzed per minute per
gram of meal), SB with 230, PP with 100 and CS was undetectable. At 60°C JBM was the
most active again with 2440 units, SB with 840, PP with 370, and CS with 70. These results
agree with the order of purified plant urease activities reported in Krajewska et al. (2009)
with the exception that PP is reported as having a higher activity than SB and CS.28
However, this difference, as well as the higher rates of activity reported as 650-800 units
per g of meal for SB, and 145 units per g of meal for CS, can potentially be attributed to
17 the difference in PP source used within this study.28 JBM demonstrated the highest activity
in comparison to other plant-based sources of urease. The activity determined as 590 –
2440 units per g of JBM meal is in rough agreement with the manufacturer’s information
that states 1500 units per g of JBM (Sigma-Aldrich Product Specification). Also, control
studies comparing filtered vs. unfiltered ground urease sources showed no difference in
ureolytic activity between the sources investigated (data not shown). Due to the
significantly higher ureolysis rates, JBM urease was chosen for the remainder of the
experiments.
Temperature-Dependent Kinetics of Urea Hydrolysis by Jack Bean Meal
Results from batch experiments performed at temperatures between 20 and 80°C
are shown as the change in urea concentration over time (Figure 2.1). Urea hydrolysis rates
increased with increasing temperatures to an optimum around 60°C for the reference time
frame of two hours. Complete hydrolysis of 20 g*L-1 urea was achieved within 60 minutes
at 60°C. For temperatures < 60°C, urea hydrolysis appeared to occur at lower rates; for
temperatures of 65°C and 70°C, ureolysis appeared to be higher initially (i.e.
approximately within the first 30 minutes) but appeared to slow down rapidly afterward,
presumably due to urease inactivation. Urea hydrolysis indeed occurs at temperatures
above 70°C but ceases after 60 minutes at 75°C and 45 minutes at 80°C, with 31.7% and
52.5% of the urea left in the system, respectively. It was observed at temperatures above
65°C over two hours, that the urea provided was not entirely hydrolyzed indicating that
complete thermal inactivation of JBM urease occurred.
18
Figure 2.1. Urea concentrations (g*L-1) over time (minutes). Temperatures ranged from 20 to 80°C (10°C increments displayed here).
JBM not exposed to elevated temperatures was observed to hydrolyze 60% +/- 5%
(average +/- standard deviation, n=3) of urea from 20 g*L-1 at 30°C within the reference
time frame. JBM urease showed more than 97% inactivation after approximately 168 hours
during exposure at 50°C, 96 hours at 55°C, 48 hours at 60°C, 24 hours at 65°C, 5 hours at
70°C, 3 hours at 75°C and 0.5 hours at 80°C. Illeová et al. (2003) noted that inactivation
rates for purified urease appear to be slower for an enzyme that is not considered
thermostable, reporting a wide range of activity loss from 50% after 50 hours at 55°C to
almost complete loss after one hour at 87.5°C. Aside from the different urease purity used
within this study, Illeová et al. (2003) noted using a 0.1M phosphate buffer at pH 7.0
throughout their study. This difference could have aided in preserving the enzyme as the
urea is hydrolyzed (which increases the pH). The results presented in this thesis revealed
that ground urease experienced 50% activity loss after 13 hours at 55°C to complete loss
after one hour at 80°C.
0
5
10
15
20
25
0 100 200 300 400 500
Urea (g*L
‐1)
Time (min)
20°C
30°C
40°C
50°C
60°C
70°C
80°C
19
Figure 2.2. Residual activity (ln[A*A0-1]) of jack bean urease exposed to various
temperatures (5°C increments from 50-80°C) for different amounts of time (180 minutes [3 hours] – 10,080 minutes [168 hours]). A non-linearized plot of the residual enzyme with a higher resolution near the beginning of inactivation can be found in the supplemental information as Appendix Figure A.3.
Results of the first-order inactivation model (Equation 2.5) for urease inactivation
between 50 and 80°C were plotted with the Arrhenius type equation (Figure A.1). The
resulting kd(T) values or slopes of the lines in Figure 2.2 are summarized in Table A.3.
These values were fitted with an Arrhenius type equation to estimate the first-order
temperature-dependent inactivation rate coefficient (Equation 2.8) with a R2 value of 0.99
(Figure A.1). The inactivation energy was calculated from the kd(T) Arrhenius equation to
be -178.75 KJ/mol. Although from different enzymes, Anthon and Barrett (2002) reported
activation energies for peroxidase and polygalacturonase to be -480 and -411 KJ/mol
(respectively). The coefficients obtained from each model for temperatures between 20 and
80°C are summarized in the Appendix as Table A.4 as well as the correlation coefficients
-10
-9
-8
-7
-6
-5
-4
-3
-2
-1
0
0 2000 4000 6000 8000 10000
Ln
(A*A
0-1)
Exposure Time (minutes)
Residual Activity
50°C 55°C 60°C 65°C 70°C 75°C 80°C
20 of their respective fits. The ka(T) values listed correspond to the first-order ureolysis rate
and was anticipated to depend strongly on temperature.
After estimating the kinetic coefficients for the inactivation models, three
temperatures 30C, 60C, and 80C were used to verify if each inactivation model could
estimate experimental urea hydrolysis data. These temperatures were chosen as the two
extremes and the temperature at which the highest activity of the JBM urease was observed
(60°C) in this study. As shown in the comparison of the model results to experimental data
(Figure 2.3) and the correlation coefficients (Table A.4), each model can predict the urea
consumption data with a R2 value ≥ 0.97 or better.
Figure 2.3. Predicted fit for series-type (solid line), series-parallel (long dashes) and first order (dotted) models as compared to experimental ureolysis data for 30°C (squares), 60°C (circles), and 80°C (triangles).
To further analyze the appropriateness of the three models, the resulting kinetic
coefficient(s) were plotted as a function of temperature, comparing the fit of the trendlines
(Figures A.1, A.4-A.10). To implement the kinetic inactivation models for use in field
0
5
10
15
20
25
0 15 30 45 60 75 90 105 120
Urea (g*L
‐1)
Time (minute)
21 applications, an accurate fit of laboratory data was desired, while minimizing model
complexity. Even though k1, k2, and k3 potentially could increase as the temperature
increases, they could also very easily be represented as a constant (Figure A.5).51 The
values for β developed within MATLAB® decreased as temperature increased (Figure A.6,
A.10). A sensitivity analysis of the β value revealed that there was no change in the series
and series-parallel models’ ability to match the experimental data. Therefore, a constant
value of one was chosen for β throughout the temperature range, as it did not have any
noticeable effect on the higher order model’s accuracy of predicting urea concentrations.51
The temperature-dependent equations and their correlation coefficients are summarized in
Table 2.2.
Each kinetic model analyzed in this study represented the experimental data well
(R2 > 0.95), a rate-limiting and rate-controlling analysis was conducted as another
comparison of the models. The estimated k1 values in the series-parallel model were
approximately two orders of magnitude smaller than the values for k3, indicating that the
series inactivation pathway proceeded much more slowly than the parallel pathway. Hence,
the series-parallel model exhibited a behavior similar to the first-order inactivation model.
Within the series model, it was noted that the first inactivation step from the native enzyme
to the isozyme form was rate controlling, and that the second step could be considered
instantaneous relative to the first step since the estimates for k2 for all temperatures were
always higher than for k1 (Figures A.4 and A.5). The two kinetic rate parameters (k1 of the
series-parallel model and k2 of the series model) representative of the steps mentioned in
the rate limiting analysis are the same magnitude and show a similar trend when plotted
22 versus temperature, indeed resembling the first-order model (kd for first-order, k3 for series-
parallel, and k1 for series in Table 2.2, each of which are in bold).
Table 2.2. Temperature-dependent equations and correlation values (R2) of kinetic coefficients obtained from mathematical modeling for first order, series-parallel and series-type models when plotted vs. temperature (units of [min-1]).
Conclusions
Urea hydrolysis kinetics of various plant-based ureases were investigated over a
range of temperatures (20-80°C) using experimental and modeling approaches. Jack Bean
Meal (JBM) exhibited the highest activity (590 to 2440 µmol urea*min-1 g of meal),
demonstrating an approximately 4x greater activity than SB, 7x greater activity than PP
and 34x greater activity than CS at 60°C based on the same mass of filtered plant-based
urease source. JBM was chosen for an in-depth analysis to determine the rates of ureolysis
across a temperature range of 20 to 80°C as well as inactivation rates for temperatures >
50°C. It was found that the highest ureolysis rates 7.72*10-4 to 2.16*10-2 kurea [min-1] (1.12
to 3.11*101 [day-1]) were observed in this study at 60°C with 20 g*L-1 urea hydrolyzed by
1.0 g*L-1 JBM in less than one hour. For temperatures < 60°C, ureolysis occurred at slower
rates while at temperatures > 60°C, thermal inactivation of urease resulted in lower
observed ureolysis rates. When JBM was exposed to temperatures between 50 to 80°C, >
Equation R2 value Equation R2 value Equation R2 value
kd 2.24*10-8*e((0.19*T))0.99 - - - -
k1 - - 4.10*10-9*e((0.12*T))0.27 3.39*10-8*e((0.18*T))
0.98
k2 - - 1.80*10-3*e((0.03*T))0.03 2.08*e((-0.03*T))
0.27
k3 - - 3.54*10-8*e((0.18*T))0.98 - -
First-order Series-parallel Series-type
23 97% inactivation of the urease enzyme was observed as quickly as 0.5 hours at 80°C and
as slowly as 168 hours at 50°C. Three enzyme inactivation schemes were mathematically
fitted to the experimental data. It was observed that a first-order inactivation model, in
which the native form of the enzyme is inactivated through a single-step, adequately
described the urease inactivation data across the temperature range of 20 to 80°C. While
enzyme inactivation might occur through a multi-step process, the outcome of the other
models was dominated by one rate-limiting step; thus, the simple first-order inactivation
model is deemed sufficient for predicting the progress of ureolysis-based engineering
applications such as deep-subsurface wellbore sealing or soil stabilization at temperatures
up to 80°C. Importantly, a simple model, such as the proposed first-order model, will be
less computationally expensive to implement into reactive transport models, such as the
ones developed by us and others.11, 12, 14 Control and prediction of urea hydrolysis and
urease inactivation rates have important implications for the use in the subsurface. The
current study will indeed aid in developing the process for applying ureolysis induced
calcium carbonate precipitation-based technologies, recognizing that the presence of
calcium was not investigated in this study. Other considerations in controlling reaction and
precipitation rates could include: heating fluids before injection or the injection of cooler
fluids could be utilized to reduce the rate of enzyme inactivation at higher temperatures.
Additional analyses should focus on the thermal stability of the urease enzyme from
microbial sources, kinetics of the reactions under different chemical conditions such as in
the presence of divalent cations and CO2-affected brine, and the kinetics of thermally
induced urea hydrolysis under subsurface relevant temperature conditions.
24 List of Terms kurea – Ureolysis rate coefficient
kd – inactivation rate coefficient
k1 – coefficient of isomerization
k2 – coefficient of inactivation
k3 – series-parallel coefficient of inactivation
β – ratio of specific activities in series-type model
U – concentration of urea
U0 – initial concentration of urea
UΔt – initial concentration of urea
A – activity of urease
A0 – initial activity of urease
T – temperature
t – time
texperiment – time of kinetic experiment
texp – exposure time
R – Universal gas constant
Ea – activation energy
P – Pre-exponential factor
E – initial native form of enzyme
E1 – intermediate form of enzyme
Ed – inactivated form of enzyme
25
CHAPTER THREE
A LABORATORY STUDY TO REDUCE PRODUCED SAND IN PRODUCTION OIL
AND GAS WELLS USING CALCIUM CARBONATE PRECIPITATION
Literature Review
Produced sand is either native (from existing geology in the subsurface) or non-
native (from other sources other than existing geology, for example proppant sand) that is
unintentionally transported during oil and gas extraction. The purpose of proppant in
shale formation applications is to promote the flow of oil or gas by holding open
engineered fractures. Without the proppant in place, the formation could collapse,
shutting off production. This process of forcing the proppant into the subsurface is
commonly referred to as “frac packing” and usually utilizes high pressures and flow
rates.54 However, sand produced during oil and gas production, from either the formation
or a failed sand management practice, has caused issues to physical oil field infrastructure
(such as well casings, tubes and pumps) in offshore and onshore oil and gas wells. Oil
and gas production can be reduced by the damaging effects from transported sand.
Reduced production can occur in well pad infrastructure on the surface or in the wellbore
from sand blasting effects or pre-mature pump failure; additionally, collapses in the oil
bearing formation can occur from the large void spaces left by the transported produced
sand. 55-57
Methods traditionally used to control sand include: slotted or perforated wellbore
pipe, wire-wrapped screens, as well as, sand and gravel packs(Figure 3.1). Recently
26 additional methods for sand control have been developed and include the use of resin
coated proppant sand and in situ mineral precipitation catalyzed by the urease enzyme.55,
58, 59 In each of these cases, the purpose was to physically filter or stabilize the near
wellbore sand to manage the produced sand more effectively. Although these methods
may work for a duration, failure is common due to long term erosive effects from high
near wellbore velocities or poor installation practices.60, 61
Figure 3.1. Different methods/materials used to reduce produced sand Top left: Slotted pipe Top right: Perforated pipe Bottom Left: Wire wrapped perforated pipe Bottom Right: Sand and/or gravel packing used as a coarse filtering media to keep fine sands from reaching the mechanical screen (not pictured: resin coated proppant sand: similar to standard silica sand, but coated with a resin that is thermally activated to bond sand in place) (Not pictured: different methods of calcification: these will be discussed near the end of the Chapter 3 Literature Review). 62-65
27
Screening methods have varying degrees of success depending on the amount of
resources used to characterize the subsurface (such as drill logs and seismography) or
how carefully a well was initially drilled.66 Each well that requires screening will
potentially require a different method. For instance, low production oil wells such as
Canadian-heavy oil that are in coarse-grained formations would potentially only require
slotted pipes, whereas a medium to coarse-grained sand formation, having higher
production flow rates, would potentially require wire reinforced screens to compensate
for the increased overburden pressures encountered.59, 67 In oil-bearing shale formations,
a combination of screening methods and non-native proppant sand are typically used to
access oil and gas through engineered fractures, but standard screening methods began to
fail sooner than anticipated due to higher than expected sand flow rates during production
from extreme overburden pressures in the subsurface.67 These extreme overburden
pressures (caused by the immense amount of earth on top of the formation) potentially
can have a direct relationship to the hydrostatic pore pressure in the subsurface,
ultimately leading to higher than anticipated flow rates after hydraulic fractures are
induced with perforation guns. Over time conduits or flow paths developed for the sand
to transport with the product, resulting in sand blasting effects on the steel casings,
ultimately leading to premature wear and tear on the well infrastructure and sand
management practices used (such as slotted or perforated pipes and the addition of wire
wrapping to perforated pipes).67
Special instances where extremely high flow conditions were generated in the
subsurface from perforation guns, motivated the oil and gas industry to develop advanced
28 methods of sand and gravel packing to protect the well infrastructure from damage. New
methods of sand and gravel packing incorporated different packing orientations with
screening methods to filter fines from the produced oil and gas. This screening method by
use of various sized sands and gravels was adopted and modified from ground water well
filtration for residential use.68 Modifications made include but were not limited to: using
wire wrapped perforated pipe (for increased durability), engineered proppant sand
(designed to withstand high pressures), or varying finishing processes through specialized
tooling (enabling for more precise gravel and sand packing completions). 54, 69 In total,
these modified methods are estimated to account for more than 65% of sand control
completions in off-shore wells located in the Gulf of Mexico and mainland wells of the
United States of America.54, 69 To achieve these different gravel and sand packing
orientations, operators would use larger gravel as the last product to reach the formation
during completions. 54, 67, 69 If done properly, near-wellbore velocities would be reduced,
protecting screens from the damaging overburden pressures and/or sand blasting effects
from the produced sand.54, 67, 69 During the packing phase, it has been shown that
unwanted mixing of the fine-grained materials can occur with the gravel pack, causing a
pressure drop between the formation and the wellbore.54 Higher pressure drops require
more energy to extract the product from the subsurface; depending on how high the
pressure drop is, a reduction in productivity of a well may be more than 50%.54 In some
instances, extreme drawdown pressures may be encountered making it difficult,
sometimes uneconomical, to extract product from the subsurface.54
29
While screening, gravel packing, or a combination of screening and gravel
packing have been shown to reduce produced sand, other advanced sand control
strategies are being researched. Resin coated sand particles have been developed that
bond together in the subsurface environment when exposed to higher temperatures.58 This
technology has been shown to improve and in some cases, restore oil production in sand
producing wells. The disadvantages to using resin-coated proppants are that it is
expensive compared to ordinary proppant sand and is permanent once in place.58, 70, 71
One potential environmentally friendly, reversible alternative to other sand
control technologies, is the use of enzymatically-induced calcium carbonate precipitation.
Calcium carbonate mineralization has been suggested as a potentially efficient tool for
sealing green-house gas leakage pathways in the subsurface and improving wellbore
sealing throughout the oil and gas sector.7, 57 Calcium carbonate mineralization has also
been studied as an alternative sand control method that is economical, efficient, and non-
toxic.57, 60, 72 Laboratory experiments in sand packed reactors have shown that developing
injection strategies to promote mineralization can reduce produced sand during reversed
flow, while still being able to obtain relatively higher flow rates within the reactor.57, 60, 72
These experiments have been scaled up and applied to existing oil wells, successfully
reducing produced sand within unconsolidated sand formations. 57, 60 Each experiment
looked at the effects of enzymatic calcium carbonate precipitation within one perforation
and the ability for the mineralization to reduce the produced sand (Figure 3.2). The
mineralization was tested in each experiment by reversing the flow, simulating flow
conditions where product would be extracted from the subsurface. 57, 60, 72 Fluid
30 velocities reported ranged between 8.8 and 52 cm*sec-1 for perforations of 3 mm and 4.4
mm for Fleming et al. (2012) and Bansal et al. (2014), respectively. At these velocities,
Fleming et al. (2012) reported a total of 2.38g of sand produced for 2 mineralization
injections (density of sand was not reported, therefore % mass produced was not
available). Bansal et al. (2014) reported 1% sand production at maximum flow rate with
10 mineralization injections.
Figure 3.2. Reactor configuration used by Fleming et al. (2012) and Bansal et al. (2014). In these two experiments, mineralization was induced in a sand packed core, after which one end was replaced with a flow restriction to simulate a fracture.57, 72
Laboratory studies within this chapter focused on mimicking a sand producing oil
well. Literature did not reveal other researchers accounting for more than one fracture or
perforation in a horizontally oriented wellbore packed with proppant sand. This work
investigated calcium carbonate mineralization applied to sand packed horizontal wellbore
31 analog reactors with multiple perforations and its ability to reduce produced sand. As
mineralization solutions were applied to this system, the sand particles were hypothesized
to be bonded together by the calcium carbonate precipitates. As a conglomerate or larger
mass of sand was created near the perforation, less sand was produced during flowback.
Materials & Methods
Reactor Design & Configuration
The horizontal wellbore analog reactor was designed to mimic subsurface
conditions within horizontal oil and gas wells, commonly found in oil fields that have
production sand issues (Figure 3.3). The reactor allowed for visual observation of
proppant sand control using clear PVC pipe as the reactor shell as a viewing window. The
flow paths within the reactor were intended to represent a horizontal well with a
perforated casing with 40/70 proppant sand between the well casing and formation
(Figure 3.4). Two phases of fluid flow were used during this experiment: one to promote
mineralization and the other to produce sand (production flow). These two phases will be
discussed in more detail in the Operations Strategy section. Two analog reactor
experiments were conducted to observe any preliminary differences between two
common urease sources, Sporosarcina pasteurii, and Canavalia ensiformis (jack bean)
meal.
32
Figure 3.3. Typical horizontal oil well with fractures. Proppant sand is forced into the fractures (shown in blue). During product extraction, unwanted proppant sand is transported to the surface with the product. 73
Figure 3.4. Computerized drawing of the sand packed analog reactor (without sand) created in SolidWorks® (1) removable end cap used to load/unload the reactor and sample after each experiment (2) gasket (3) metal clips used to hold end cap in place (4) perforation ports on inner piping to mimic holes in wellbore casing (5) inner piping to mimic subsurface wellbore casing (6) outer PVC shell (7) valves.
The outer diameter of the reactor was 6.63” [16.83 cm] (wall thickness of 0.28”
[0.70 cm]) with an inner pipe diameter of 2.38” [3.04 cm] (wall thickness of 0.154” [0.39
33 cm]). The length of the inner pipe was designed to be 17.32” [43.98 cm], nine (9) 1/8”
[0.32 cm] perforations were drilled through the inner pipe in a helical manner. The
perforation orientation was designed to mimic perforations through a horizontal casing in
a hydraulically fractured oil and gas well (Figure 3.5).74 The fittings on the exterior of the
reactor were chosen to be 0.75” [1.90 cm] to allow for use of common pipe hose
attachments and to reconfigure the reactor between the two phases of each reactor
experiment.
Figure 3.5. Perforation gun (left) and helical perforation pipe (right). Perforation guns use a directional explosive to create a conduit into shale formations to access hydrocarbons. A helical perforation pipe has engineered failure points to create a design pattern for accessing hydrocarbon bearing formations.75, 76
Proppant sand was used in both reactor experiments, specifically 40/70 proppant
BadgerFracTM (Badger Mining Corporation of Berlin, WI). Proppant sand is typically
comprised of poorly graded (uniform) spherical silica sand, a desired characteristic in oil
field applications. The uniform size and shape allow space between the sand particles,
promoting higher permeability compared to a non-uniform sand (or well graded,
containing a broad range of sizes) (Figure 3.6). A non-uniform proppant sand potentially
34 would contain fines and irregular spherical shapes, restricting fluid flow more than a
uniform proppant sand.
Figure 3.6. Uniform proppant sand (left) vs. non-uniform sand (right). Uniform sand encourages a packing orientation that allows for void spaces (white area between the blue circles) between each sand particle, promoting free flow of fluids. A non-uniform sand contains fines that potentially could plug the void spaces, restricting flow within the sand pack. Media & Injection Fluids The analog reactor experiments used three fluids to promote mineralization; 1) a
solution containing the urease source to promote urea hydrolysis, 2) a source of calcium
and urea to induce the precipitation of calcium carbonate within the reactor, and 3) a
brine solution to separate inoculum and calcium pulses (minimizing instantaneous
calcium carbonate precipitation) as well as flush the reactor after the second calcium
pulse to reduce residual carbonate that may precipitate instantaneously. The inoculum
and calcium-containing media were both based on the Yeast Extract (YE+) medium
(Table 3.1) (Yeast Extract was omitted for the enzymatic reactor). Yeast extract aids
microbial growth but was not necessary for the jack bean urease to be active.
35
Table 3.1. Analog Reactor Experiment Media Recipes (Stock Solutions) Media Chemical Concentration
g*L-1 (M)
YE- (Growth media) *Not pH adjusted*
Urea Sodium Chloride Ammonium Chloride Yeast Extract (Acros)
24 (0.40) 24 (0.41) 1 (0.02) 1
YE+ (Mineralization Media)
Urea Sodium Chloride Ammonium Chloride Yeast Extract (Acros) CaCl2*2H2O (Peladow)
24 (0.40) 24 (0.41) 1 (0.02) 1 13.3 Ca2+ (0.33)
Brine rinse solution Sodium Chloride 24 (0.41)
Operations Strategy
Two mineralization experiments and three control (non-mineralization)
experiments were conducted in the analog reactor. Control experiments 1-3 were
completed to develop a baseline of sand produced during high flowrates for comparison
to the amount of sand produced with the microbial and enzymatic reactor experiments.
The experiments used two different urease sources to investigate their ability to manage
sand under similar injection strategies. Two common sources of urease were used in these
experiments, Sporosarcina pasteurii in the first experiment and Canavalia ensiformis
(jack bean in meal form) in the second.
Proppant Loading
The proppant sand used for these experiments displaced easily, making it difficult
to load the analog reactor. To ensure a minimal amount of sand displaced into the inner
pipe through the perforations during loading, a loading process was developed. The
36 reactor was oriented vertically and the lower valve was closed (Figure 3.7). Water was
added to the reactor from the 6” [15.25 cm] open end, wetting the sand and reducing its
ability to displace as more sand was added. Once full, excess sand was removed from the
slide cap zone, where the end cap would be added to seal the reactor. The end cap was
slid onto the end, sealed and then the reactor was moved back into a horizontal
orientation for either a control or mineralization experiment.
Figure 3.7. Proppant sand loading configuration. Once the reactor was completely full, excessive pressure generated from the 6” [15.25 cm] cap being slid into place could be released using the valve on the side of the reactor connected to the water supply line (hose in right of figure).
37 Microbial Inoculum Preparation
Microbes were grown by adding 1 mL of Sporosarcina pasteurii (ATCC 11859)
thawed frozen stock to 100 mL of autoclaved brain heart infusion (Becton Dickinson)
solution (37 g*L-1) amended with 2% by weight urea. Day 1: The organisms were
incubated at 30°C on a shaker at 150 rpm for 16 hours. Day 2: After the incubation
period, 30 mL of the culture was transferred to 270 mL of fresh, autoclaved brain heart
infusion media. The transferred organisms were incubated at 30°C on a shaker at 150 rpm
for an additional 16 hours. Day 3: After the second incubation period, the contents were
transferred to 2700 mL of YE- media, now considered the inoculum. For all subsequent
days following Day 1, an aliquot of the first 16-hour culture was used to inoculate 100
mL of fresh, autoclaved brain heart infusion in place of the frozen stock.
Mineralization Fluid Injection
A Cole-Parmer Instrument Co. Peristaltic Pump (Model Number 7553-80) was
used for the mineralization injection phase. Two pump heads (Masterflex® Easy-Load®
II Model 77200-62) were used in parallel during mineralization for the microbial and
enzymatic experiments to provide flowrates sufficiently high to achieve a target residence
time of 15 minutes (Figure 3.8). During the mineralization phase, fluids were injected
into the reactor through the inner pipe, out of the perforations, into the sand pack, then
out of the exterior PVC pipe (Figure 3.9).
38
Figure 3.8. Mineralization flow phase. Fluids were pumped from left to right using the Peristaltic Pump. Effluent was collected in 20L carboys (not pictured) that could easily be transferred to the autoclave.
Figure 3.9. Flow schematic of mineralization flow phase. (1) Inlet (2) Inner pipe where fluids would enter (3) Perforations where fluids would leave the inner pipe and enter the sand pack (4) Sand pack (extends for length of reactor) (5) Outer PVC pipe (6) outlet.
Inoculation of the reactor was performed in the morning, prior to injection of
calcium containing solutions. One reactor fluid volume (3L) of inoculum was injected,
followed by ~ 1 L of brine (reducing instantaneous precipitation in tubing and inner
39 annular space). A 1-hour stationary period followed the inoculum injection to allow the
microbes/enzymes to adsorb to the surfaces. It is not entirely known how much of the
enzyme sorbs in a defined time frame. It should be noted that quantifying attachment of
the microbes or enzymes was not conducted within these studies. Following the
stationary period, two pulses of YE+ (calcium and urea containing medium) were
injected with 120-minute stationary periods between injections. Two reactor fluid
volumes of brine rinse were injected after the YE+ injections to flush the majority of
residual carbonate from the reactor. The rinse reduces the risk of instantaneous
precipitation during the next urea containing volume injection. This process was
continued for a total of five inoculations and ten YE+ pulses.
Production Flow
Production flow was the flow phase used in this experiment to mimic field
conditions where proppant sand is produced when oil and gas is extracted (i.e. the flow
direction is from the formation to the wellbore and on to the surface). This procedure was
used in the control experiment to quantify the amount of sand that could be produced in
this system without mineralization, as well as in the microbial and enzymatic experiments
to compare the difference in sand produced with mineralization. During the production
phase, a ¾” [1.90 cm] transfer pump (Drummond 1/10 HP, Harbor Freight) was used to
move the fluid through the reactor, simulating conditions like production within a
wellbore with sand near the perforations. Flow in this configuration was opposite from
the mineralization phase to simulate field like conditions, where product would be
extracted from the formation (Figure 3.10).
40
Figure 3.10. Flowback or production phase. In this setup, fluid was supplied from the constant water supply to the reactor. It would flow through the mineralized sand pack at high enough velocities to erode the sand pack. Once out of the reactor, it would flow through the 1 ½” PVC proppant sand collection tube where the sand would settle and collect.
A 1 ½” PVC pipe (shown in Figure 3.10) served as a sand collection device (trap)
during production flow operations, collecting any sand leaving the reactor. Standard
0.75” [1.90 cm] garden hose filters were installed at the end of the sand collection tube to
restrict sand from reaching the pump.
A base-line flow within the reactor without sand was established with the transfer
pump using the configuration in Figure 3.10. Each production flow experiment was run
for 5 minutes while measuring the flowrate every minute. Sand produced during control
41 experiments 1-3 and the mineralization experiments was collected, dried in an oven at
100°C until consistent dry weight was obtained.77
Fluid Sampling Influent mineralization media were sampled every morning for pH, calcium, urea,
and microbial concentration (Jack bean meal was prepared at a known concentration and
does not contain a microbial source, therefore microbial concentrations were not
determined for the enzymatic reactor experiment). Calcium and urea were measured in
the effluent at the end of every YE+ pulse. Samples for microbial concentrations were
taken from the inoculum suspension and effluent samples (microbial reactor experiment
only) after the second calcium pulse to verify microbial activity was present after the
stationary period. Samples for the microbial experiment were syringe-filtered prior to
performing pH, urea, and calcium assays to remove microbes. Samples for urea analysis
were diluted in 10% sulfuric acid (main acid used in Jung assay) and samples for calcium
analysis were diluted in 10% nitric acid (main acid used in calcium assay) to inactivate
the microbes and enzymes. The pH was measured immediately for both reactor systems
before the samples were added to acid.
Jung Urea Assay Urea analysis was performed using a colorimetric, absorbance-based plate assay
adapted from Jung et al. (1975) (as presented in Phillips et al. 2013). The absorbance
measurements were taken at 505 nm by a BIOTEK Synergy HT plate reader. The
samples were compared to known standard concentrations.
42 Calcium Assay Calcium analysis was performed using a colorimetric, absorbance assay adapted
from Clini Chem’s Calcium OCPC/AMP protocol performed in multi-well plates to
facilitate throughput.78 The absorbance measurements were taken at 575nm using a
BIOTEK Synergy HT plate reader. The samples were compared to standards with known
concentrations.
Cell Population Analysis The presence of microbes within the microbial experiment was verified using a
cell counting technique. Suspended viable cell counts were conducted using the drop
plate method.79 To perform suspended cell counts, 1 mL of unfiltered sample was
transferred into 9 mL of 1 x concentration Phosphate Buffer Solution (Table 4). Samples
were serially diluted and 10 µL of selected dilutions were plated on BHI agar plates
amended with 20 g*L-1 urea. Plates were dried at room temperature for 2 hours, then
transferred to a 30°C incubator for 16-24 hours, after which colony forming units (viable
cells) were counted.
43 Table 3.2. Media recipe to make 1x Concentration Phosphate Buffer Solution for suspended cell counts. Media should be prepared in previously autoclaved glassware. Once media is mixed, autoclave one more time.
1x Concentration Phosphate Buffer Solution
Compound Concentration
NaCl 8.5 g*L-1
KH2PO4 0.61 g*L-1
K2PO4 0.96 g*L-1
Adjust pH to 7.0 Filter sterilize or autoclave
Imaging Sand samples extracted from the microbial and jack bean meal experiments near a
perforation were imaged to identify/detect mineral formation. Light microscopy imaging
was conducted using a Stereomicroscope, Leica Model MDG41 (Center for Biofilm
Engineering Microscopy Facility, Montana State University). Electron microscopy
imaging was performed using a Zeiss Supra 55VP Field Emission Scanning Electron
Microscope (Image and Chemical Analysis Laboratory, Montana State University).
Samples were coated with iridium at 20 mA for 30 seconds prior to imaging.
Results & Discussion
Fluid Sample Analysis The amounts of urea hydrolyzed during each YE+ pulse in the microbial and
enzymatic experiments were calculated by monitoring a decrease in effluent urea
concentrations compared to the known influent concentration. The influent urea
concentration was determined from YE+ stock solutions prior to injection. Effluent
44 samples were collected after the two-hour residence time for YE+ injections. The purpose
of this technique was to obtain a residual urea concentration from the batch period that
could help predict calcium precipitation. Data from both experiments are displayed as a
percentage of urea hydrolyzed (Figure 3.11).
Figure 3.11. Percentage of urea hydrolyzed for the microbial and enzymatic experiments vs Number of YE+ pulses. Bold vertical lines denote a new injection of microbes or enzymes. High percentages reflect high urea hydrolysis whereas low percentages reflect poor urea hydrolysis. Both sets of data indicated that the urease sources were present and actively
hydrolyzed urea. Overall the enzymatic reactor experiment hydrolyzed more urea than
the microbial reactor in each YE+ pulse. Within the microbial reactor experiment, the
urea hydrolysis did not increase a substantial amount (more than 50%) until the final YE+
pulse. It was noted that prior to pulse 6, a preferential flow path within the reactor may
have been present. It was hypothesized that two phenomena may have been occurring
0%
10%
20%
30%
40%
50%
60%
70%
80%
90%
100%
1 3 5 7 9
%U
rea
Hyd
roly
zed
Number of YE+ Pulses
Microbial Experiment
Enzymatic Experiment
45 within the reactor: it (the preferential flow path) may have allowed the majority of the
inoculum to flow through the reactor without significantly interacting with the proppant,
resulting in a substantially reduced the amount of urease being retained in the microbial
reactor relative to the enzymatic reactor. There were no visible preferential flow paths
within the enzymatic reactor. Thus, the amount of urea hydrolyzed was much higher
(more than 40% for each pulse).
Figure 3.12. Calcium removed (shown as a percent) for the microbial and enzymatic experiments vs. Number of YE+ pulses. Lower percentages of calcium removed indicate less calcium precipitation whereas high percentages of calcium removed indicate more possible calcium precipitation. Calcium concentrations are dependent on available carbonate for precipitation, therefore a large fraction of calcium removed reflects high hydrolysis during that YE+ pulse. The average calcium precipitation for the microbial experiment was less than the
enzymatic experiment, which is explained by recognizing the amount of urea hydrolyzed
was low for most of the experiment (Figure 3.12). Calcium and carbonate (from urea) are
0%
10%
20%
30%
40%
50%
60%
70%
80%
90%
100%
1 3 5 7 9
% C
alci
um R
emov
ed
Number of YE+ Pulses
Microbial Experiment
Enzymatic Experiment
46 precipitated in a 1:1 stoichiometric ratio. In other words, if an equal amount of carbonate
species were not present, calcium would not be precipitated from solution.
pH Analysis
Another indicator of positive ureolytic activity is to monitor for increases in pH
values. The inoculum pH values for the microbial reactor were between 9.1-9.3, a normal
range for a microbial suspension containing S. pasteurii. The pH for the YE+ media
ranged from 7.2 – 7.9, indicating there may have been contamination in the YE+ media
used for YE+ pulses 5-7, but could have just been variability in the media that was made
(media was not sterilized or pH adjusted prior to use to simulate a field like application).
The rise in pH of the effluent samples indicated that ureolysis occurred within the reactor,
supporting conditions for carbonate precipitation (alkaline pH range) (Figure 3.13). The
pH values of the enzyme solutions for the enzymatic experiment were between 5.9 and
6.1 prior to injection. The pH values of the YE+ media varied from 7.2 to 7.4 (media was
not sterilized). Effluent pH values after the YE+ pulses increased to a range of 8.9 to 9.4
(Figure 3.14).
47
Figure 3.13. pH vs. Number of YE+ Pulses for the Microbial Experiment. As pH increased throughout the 2-hour shut in period, conditions favorable for calcium carbonate precipitation were being met. This is achieved by the urease-catalyzed hydrolysis of urea.
Figure 3.14. pH vs. Number of YE+ Pulses for the Enzymatic Experiment. As pH increased throughout the 2-hour shut in period, conditions favorable for calcium carbonate precipitation were being met. This is achieved by the urease-catalyzed hydrolysis of urea.
6
6.5
7
7.5
8
8.5
9
9.5
1 3 5 7 9
pH
Number of YE+ Pulses
Microbial Reactor
Inoculum YE+ Media YE+ Effluent
4
5
6
7
8
9
10
1 3 5 7 9
pH
Number of YE+ Pulses
Enzymatic Reactor
Enzyme source YE+ Media YE+ Effluent
48 Viable Cell Counts Population assays for the inocula indicated that between 1.4x106 and 5.5x107 CFU*mL-1
were present initially. The cell populations measured after the 2-hour stationary period
were between 1.8x106 and 9.8x106 CFU*mL-1, verifying that there could be a significant
amount of S. pasteurii still present and active within the reactor.
Flow Rate Reduction
Flow within this analog reactor system without sand was considered a non-
constricted flow condition. Once sand was added to the system (as done in the control
and mineralization experiments) it was observed that the effluent flow decreased due to
the sand and sand + mineralization. The maximum flow attainable within this reactor
system without sand was determined to be 14 L*min-1. Using the same pump, the effluent
flow of the control experiments (sand only) were potentially restricted by the
accumulation of produced sand in the 1 ½” PVC collection tube, reducing the average
flow to 1.6 L*min-1 (an 88% reduction). The averaged effluent flow for the microbial and
enzymatic experiments were 2.9 L*min-1 (a 45% increase) and 3.0 L*min-1 (a 47%
increase), respectively (Table 3.3). These increased flow rates compared to the control
experiments could be attributed to the reduction of produced sand accumulated in the 1
½” PVC collection tube during the control experiments, reducing the flow restrictions
that were might have developed in the control experiments. The mineralization
experiments showed that flow potentially can be restored or increased in sand producing
systems (like the reactor developed here) or in larger, subsurface oil wells, by decreasing
49 the amount of produced sand that potentially would be deposited at another location
within the system.
Flow velocities obtained within the analog system were sufficiently high to
transport sand near the perforations, 37.5 cm*sec-1 and 67.8 – 70.2 cm*sec-1 in the
control and mineralization experiments, respectively (Table 3.3). These velocities were
much higher than those used in Fleming et al. (2012) (8.8 cm*sec-1) but comparable to
Bansel et al. (2014) (52 cm*sec-1). Although similar flow rates to Bansel et al. (2014)
were achieved, variations in reactor configuration such as analyzing only one perforation
and different mineralization protocols (addition of bentonite and mineralization injections
twice every 24 hours) don’t make it a direct comparison.
50 Table 3.3. Effluent flow data representing key points during the control and mineralization portions of the analog reactor experiment. Effluent flow velocity was calculated by dividing the effluent flow (cm*sec-1) by the cross-sectional flow area of the effluent tubing inner diameter. The flow velocity at a single perforation was calculated by assuming the total influent flow to the inner pipe was equal to the effluent flow. The effluent flow was divided by the number of perforations (9) to get the flow at one perforation. Once converted to [cm3*sec-1], the flow velocity could be calculated by dividing the volumetric flow by the cross-sectional area of one perforation. (Note: the total cross-sectional area for the (9) perforations is nearly equal to the total cross-sectional area for the effluent piping. Had larger perforations been used, the flow velocity at the perforation would be much lower that the effluent velocity due to a larger total flow area)
Avg. Effluent Flow from
Reactor (L*min-1)
Effluent Flow Velocity from
Reactor (cm*sec-1)
Avg. Flow at one
Perforation (L*min-1)
Flow Velocity at One
Perforation (cm*sec-1)
No Sand 14.0 315.3 1.6 327.0
Control Experiment (Sand Only)
1.6 36.1 0.2 37.5
Microbial Experiment
(Sand + CaCO3) 2.9 65.4 0.3 67.8
Enzymatic Experiment
(Sand + CaCO3) 3.0 67.7 0.3 70.2
Cross Sectional Flow area [cm2] 0.738 cm2 0.079 cm2
Produced Sand Collected
The total mass of sand capable of fitting in the annular space of the analog reactor
was roughly 9 kg, depending on how much sand entered the inner pipe during loading.
The control experiments produced 5.9 to 6.5% of the total sand mass (Table 3.4). After
each control experiment, it appeared a substantial amount of the sand migrated to the
center pipe of the reactor or into the 1 1/2" PVC collection tube (Figure 3.15). During
reactor sampling, it was noted that a large amount of sand was deposited within the
smaller pipe and within the ¾” [1.90 cm] effluent piping. These deposits may have been
51 caused by a backup in the collection tube (which was completely full when removed from
the system). Based on these observations, it is possible that the maximum amount of sand
was produced with this setup.
Figure 3.15. Control experiment reactor imaging and proppant sand collection (typical) Left: Typical proppant sand level within reactor after control experiment 1-3. Deposits of sand inside the inner pipe most likely account for a large amount of the displaced proppant sand throughout the reactor. Right: Typical amount of proppant sand collected from tube downstream of the reactor after production flowback during control experiments. This was the mass of sand considered produced from the reactor. (Note: Although a quantifiable amount of sand was collected downstream as shown in the figure to the right, the mass reported is substantially lower than the actual amount of sand that was displaced during the control experiment. The additional displaced sand is shown in the left image, the visible deposits of sand in the inner pipe) Table 3.4. Mass of proppant sand collected in the pan for control experiment 1-3 and statistical analysis (mass of sand in the inner pipe was not quantified). The relative standard deviation of mass of sand produced being lower than 5% shows there was little experimental variability within the control experiments.
Mass collection data Control experiment 1 2 3
dry pan wt (g) 476 474 474
pan wt. with sand (g) 1104 1046 1088 Mass of sand produced (g)
628 572 614
Mass % produced 6.5% 5.9% 6.3%
52 Sand Production within the Microbial & Enzymatic Experiments
The mineralization within the sand packs could effectively control the sand during
the initial 5-minute production flow test, producing only 0.6 g in the microbial
experiment and 3.4 g in the enzymatic experiment. After the initial 5-minute production
flow test a 30-minute flow test was added, producing only 0.2 g more sand in the
microbial experiment and 3.2 g more in the enzymatic experiment.
The amount of sand produced from the microbial and enzymatic experiments
were less than the mass produced from the control experiments. Sand migration within
the annular space was not obvious during the production flow tests for either
mineralization reactor. The microbially and enzymatically induced calcium carbonate
precipitates effectively reduced the amount of produced sand by 98% or more. There was
only 0.01% sand produced in the microbially treated reactor and 0.07% sand produced in
the enzymatic reactor (using 10 calcium pulses). In both experiments the fluid velocity at
one perforation was calculated to be 67.8 – 70.2 cm*sec-1. (Table 3.5). Bansal et al.
(2014) reported using 10 calcium pulses, resulting in 1% sand produced after a fluid
velocity of 52 cm*sec-1 was induced on their mineralized sand pack. Fleming et al.
(2012) reported using only 2 calcium pulses, resulting in the subsequent production of
2.38 g of sand at a fluid velocity of 8.8 cm*sec-1 (a percent of total sand pack or sand data
was not given). Results from the microbial and enzymatic reactor experiments appear to
be an improvement compared to these previous works. Additional replicate experiments
will need to be conducted to verify results.
53 Table 3.5. Mass of proppant sand produced from the microbial and enzymatic experiments. Each reactor reduced the amount of sand produced from the control experiments by 98% or more.
Microbial Enzymatic wt (g) 5 min 30 min 5 min 30 min dry pan 11.2 11.2 11.4 11.3 pan with sand 11.8 11.4 14.8 14.5
Mass of sand 0.6 0.2 3.4 3.2
Total sand (g) 0.8 6.6
Mass % produced 0.01% 0.07%
Average mass % Produced (control) 6.2%
% mass reduction ==> 99.9% 98.9% Reactor Sampling and Mineralized Sand Observations Visual observations of the mineralized sand pack and yield strength of the
mineralized sand during destructive sampling revealed potential differences in the
mineralized sand packs from the two enzyme sources (Figure 3.16). The reactor from the
microbial experiment was sampled first. The mineralized sand pack held its shape once
the cap was removed, potentially due to precipitation throughout the sand. Samples
collected further away from perforations (i.e. near the outer PVC pipe) also retained their
shape and required a substantial amount of physical force to break up the sand pack
(Figure 3.17).
Immediately after the end cap was removed from the enzymatic experiment
reactor, a substantial amount of sand that appeared to have not been mineralized, was
displaced from the reactor together with the remaining fluid. The sand remaining in the
annular space between the large outer PVC pipe and the inner pipe presumably was
mineralized (was not verified due to destructive sampling method used to collect
54 samples). Samples from the enzymatic reactor required noticeably less physical force to
remove, potentially due to ad- and cohesion compared to the samples from the microbial
reactor.
The mineralized sand pack from the microbial experiment appeared to have a
higher structural strength compared to the mineralized sand pack from the enzymatic
experiment. This observation could potentially be attributed to the difference in the
enzyme sources’ attachment/sorption density to the sand (microbial attachment and
enzymatic sorption was not assessed in these experiments). For example, the microbes
may have attached to the sand surface at higher concentration or attached more readily
than the free enzymes during the 1-hour attachment period after inoculation. The attached
microbes then could have acted as a nucleation source for mineralization, potentially
creating a denser mineralized sand pack than the seemingly more homogenous enzymatic
mineralization.
55
Figure 3.16. Mineralized sand pack from the microbial (left) and enzymatic (right) experiments. It was apparent that precipitation occurred throughout the entire sand pack within the microbial reactor whereas precipitation within the enzymatic reactor was localized near the inner pipe.
Figure 3.17. Mineralized samples from the microbial (left) and enzymatic (right) experiments near the inner pipe. Grooves marks left by the sampling device in the microbial reactor sample show that dense mineralization occurred throughout the sand pack. If the remainder of the sample had not been as densely mineralized, it would have yielded before the sampling device left groove marks. The smooth surface of the enzymatic reactor is from mineralization occurring near the inner pipe. The mineralized sand from the enzymatic reactor was brittle and easily broken by hand.
56 Post Experiment Imaging Imaging was done on mineralized sand samples near a perforation within the
center length of the two analog reactor experiments. This location was chosen to observe
the sand near the perforation where mineralization fluids were introduced into the sand
pack. A sample from the microbial reactor experiment revealed a tunnel that formed in
the region of the perforation leading into the sand pack.
This tunnel potentially formed as a result of selective fluid channeling through the
proppant sand. As the fluid was pumped through the system at a high flow rate, the fluid
would more readily follow the path of least resistance. This continuous flow through a
selected area in the sand pack would create a tunnel-like flow pathway. As the tunnel
formed, precipitation would occur on the sand, creating a stable structure. (Figure 3.18).
Figure 3.18. Detailed photos of the calcified tunnel. Top: The calcified sand sample is completely intact. The face out of the picture would sit on the inner pipe face with a perforation near the tip of the arrow. Bottom left: (Left hand side of fracture) Sample was fractured, revealing a calcified tunnel leading into the sand pack. Bottom middle: Right hand side of fractured sample with remaining tunnel. Bottom right: Entry hole of calcified tunnel.
57
Stereoscope images of the mineralized tunnel revealed densely calcified sand near
the opening, potentially serving as a support structure to deliver the mineralization fluids
into the sand pack (Figure 3.19). Additional imaging showed that the calcified tunnel
appeared to decrease in diameter (or constrict) as it continued into the sand pack. This
observation supports the hypothesis that mineralization may be able to cement proppant
into larger masses, reducing movements of the sand, but potentially allowing fluids to
pass through the sand pack. Other perforations between the microbial and enzymatic
experiments contained structures like the tunnel shown in Figure 3.18 but were not as
defined (Figure 3.20).
Figure 3.19. Stereoscope image of calcified tunnel from the microbial experiment. Image taken of calcified tunnel (bottom middle image of Figure 19) approximately 0.05” x 0.1” [1.25 mm x 2.5 mm] (Perforations were 0.125” [3.20 mm] in diameter). *Image taken by Neerja Zambare.
58
Figure 3.20. Stereoscope image of sand obtained from the enzymatic experiment samples revealed that potential mineralization occurred on the surface (white specs in image) and potentially less mineralization further below the surface. Circled areas may be less obvious tunnels that could have served as media delivery pathways within the sand pack. A more detailed Field Emission Scanning Electron Microscope (FESM) image of the areas that potentially have mineralization can be found in Figure 3.21. *Image taken by Neerja Zambare.
Figure 3.21. FESM image of potential calcium carbonate precipitation occurring on sand obtained from the enzymatic experiment samples. The calcium carbonate aggregates formed from free enzymes have a smoother surface than those formed from microbes. Microbially precipitated calcium carbonate aggregates typically (but not always) have a rough surface due to nutrients in solution, biofilm growth on the surface, or microbial entombment. *Image taken by Neerja Zambare.
59 Additional imaging using FESEM revealed interfacial bonding between sand
particles, possibly due to mineralization. These images show that biomineralization could
bond proppant sand particles together, potentially allowing for fluid passage between the
bonded sand particles. When biomineralization is applied to situations where sealing is
not desired, it has the potential to provide fluid passage within a sand pack while
constraining movement of sand particles (Figure 3.22).
Figure 3.22. Two proppant sand particles bonded together, potentially by two calcium carbonate aggregates, allowing a gap for fluid passage. This sample was from the microbial reactor. *Image taken by Neerja Zambare.
60
Conclusions
The horizontal wellbore analog reactor experiments successfully extended upon
previous work by Fleming et al. (2012) and Bansel et al. (2014) by applying calcium
carbonate precipitation to multiple perforations and testing for improved sand control.
High flow rates applied to the mineralized sand pack show that urease induced carbonate
precipitation (microbial and plant sourced enzymes) can potentially manage sand in
subsurface conditions where the sand is transported from its target location to an
undesired location. Without mineralization (control experiments), sand was able to
migrate into the sand collection tube, creating a measurable flow restriction. Flow rates in
both the microbially and enzyme-treated reactors improved to approximately 3.0 L*min-1,
compared to 1.6 L*min-1 in the control reactors without mineralization treatment,
presumably due to the mineralization restraining the sand from collecting in the sand
collection tube. These results indicated that mineralization could restore or improve oil
well production conditions otherwise restricted by transported sand.
Due to variability and lack of repeated experiments within this work, additional
studies will be required to determine which urease source is more effective and to
optimize this potential application. Temperatures, existing chemicals, pH values and
inhibitory compounds in the subsurface will be inconsistent from one well site to the next
when mineralization is applied to control sand in field applications. To better prepare for
the possible variability in subsurface conditions, varying input parameters in laboratory
experiments such as: number of pulses and enzyme injections, flowrates (mineralization
and production phases), media concentrations and potentially immobilization of the
61 enzyme on proppant carriers will improve the likelihood of success in the prospective
field applications of this technology.
This reactor system should be considered preliminary and should be improved
before additional experiments are done. Improvements should be made to the effluent
ports on the outer shell containing the proppant sand. This would be done to potentially
reduce preferential flow paths during mineralization injections. The seal and access port
near the end cap should be improved to withstand higher pressures. The reactor started
leaking when fluids were forced into the reactor with pressures in excess of 50 psi,
forcing reactor operation with a fairly low-pressure pump. Moreover, a larger sand
collection pipe would enable more sand to be produced during the control experiments.
Larger and smaller perforations could be used in combination with a variety of injection
strategies for developing an optimum method for controlling sand in a specific well.
Also, the maximum fluid velocity withstood for a given amount of mineralization could
be determined by varying the perforation size and keeping the flow constant through the
experiments. More accurately quantifying the total mass of sand displaced after
production flow tests would also be beneficial. This potentially could be achieved by
adding a secondary barrier system on the end of the larger PVC pipe, retaining sand in
the annular space when the end cap is removed. The addition of the barrier would allow
for a sequential break down of the reactor, separating the deposited sand in the inner pipe
from the sand remaining in the annular space. A hole in the barrier, large enough for the
inner pipe to slide in and out, would be required for this type of a setup. After the inner
pipe is removed, the mass of the sand remaining in the annular space could be weighed.
62
CHAPTER FOUR
CONCLUSIONS & SUGGESTIONS FOR FUTURE WORK
The research presented in this thesis provided data applicable to the subsurface
use of urease for engineering applications. Urease sources from plants cotton seed,
Pidgeon pea, soy bean and jack bean meal (CS, PP, SB and JBM) were investigated and
compared to one another as a potential urease source for future projects. Using the same
mass concentration, Jack bean meal was the most active urease source, followed by SB,
PP and CS. The order of the most active to least active plant sourced urease did not
change in comparison to the use of unfiltered urease sources. High temperatures rendered
urease inactive within short timeframes e.g. within 15 minutes at 80°C compared to
within 168 hours at 50°C. Experiments, coupled with mathematical modeling using
MATLAB® and Excel showed that urea hydrolysis kinetics and urease inactivation can
both be described using first-order reaction rate laws. The (mathematical) combination of
these first order reaction rate laws describes urea hydrolysis by JB urease well for the
temperature range from 50 to 80°C.
A horizontal wellbore analog reactor was developed in the second part of this
thesis work that allowed to simulate the production of sand from an oil well.
Two mineralization experiments were done, each using a different urease source
(Sporosarcina pasteurii and jack bean meal (JBM)) to investigate their ability to manage
sand using similar injection strategies. The microbial and enzymatic treatment of sand in
the reactor successfully reduced the amount of produced sand. The microbially treated
63 reactor allowing less sand to be produced than the enzyme-treated reactor despite the
microbially treated reactor hydrolyzing less urea and precipitating less calcium carbonate.
Without mineralization (the control experiments), sand was able to migrate into the sand
collection tube, creating a flow restriction. Flow improved nearly 2 times of the control
experiment flow rates in both the microbially and enzyme-treated reactors, presumably
due to the mineralization restraining the sand from collecting in the sand collection tube.
FESEM imaging revealed that calcium carbonate precipitation has the potential to bond
proppant sand particles together creating a bridge, allowing flow paths between particles.
Suggestions for Future Work Additional work should be focused on expanding the jack bean meal enzyme’s
behavior when subjected to different environmental conditions that may be encountered
during mineralization in the subsurface. Ureolysis rates will change once calcium is
introduced due to urease potentially being entombed or otherwise inhibited or inactivated.
Therefore, the inactivation of urease under a variety of conditions relevant to the
subsurface will have to be studied in more detail. Additional work should investigate
different fluid chemistries like higher or lower pH values, the presence of commonly
encountered oilfield chemicals, and higher pressures. This future work would build upon
the temperature-dependent inactivation model, ultimately being integrated into the
reactive transport model that is being developed with our collaborators at the University
of Stuttgart.11, 12 Understanding how the enzyme behaves under these conditions in
laboratory environments will improve the likelihood of successful field studies.
64 The work within this thesis investigating proppant sand control should be
considered a starting point for future projects. Past mineralization work was done by
Cunningham et al. (2011, 2014), Phillips et al. (2013, 2015, 2016), and Norton (2017) to
reduce the permeability in porous media for fluid path divergence or for different sealing
purposes in the subsurface. The mineralization work within this thesis is different from
these works. Complete sealing of the sand pack was not the end goal but the goal was
rather to stabilize the sand pack by binding together the sand particles. Therefore,
successful applications of carbonate precipitation to reduce the movement of sand in the
subsurface will require additional studies to optimize injection strategies (some variations
include but are not limited to: varying flow rates, changing media and inoculum
concentrations/mixtures, varying the number of mineralizing injections, simulating
subsurface chemical environments that may have inhibitory effects on the enzyme or
microbe). This amount of detail is necessary because it is unknown how much calcium
carbonate is necessary to immobilize the proppant sand under field-like conditions.
Continuous flow systems (like the added 30-minute production flow test) or even higher
flow rate transfer pumps could be added to a mineralized sand pack to test the longevity
of the mineralization. Production water (actual water from an oil and gas well typically
contains compounds that could be inhibitory to urease) could be circulated in this
continuous flow system to add more realism.80 An extensive understanding of how the
enzyme behaves in these harsh environments, coupled with a thorough understanding of
the amount of calcium carbonate required to hold the proppant sand in place, will support
the successful advancement of biomineralization in subsurface applications.
65
REFERENCES
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71 56. Morkved, M. L.; Knight, C.; Bhagwan, B.; Garcia, A.; Zhuang, W.; Zhuang, A.; Maersk Oil, Frac Packing: Fracturing for Sand Control Middle East & Asia Reservior Review 2007. 57. Fleming, N.; Berge, E.; Ridene, M.; Ostvold, T.; Josang, L. O.; Rohde, H. C., Controlled Use of Downhole Calcium Carbonate Scaling for Sand Control: Laboratory and Field Results on Gullfaks Society of Petroleum Engineers 2012. 58. Chengqui, F., Sand Control Technology with Plastic pre-coated sand grain Society of Petroleum Engineers 1988. 59. Zaleski, T., Sand-Control Alternatives for Horizontal Wells. Journal of Petroleum Technology 1991, 43, (05), 509-511. 60. Morkved, M. L.; Knight, C.; Bhagwan, B.; Garcia Algora, A.; Zhuang, W.; Maersk Oil, Chemical Consolidation of Sand Propped Fractures in a Chalk Reservoir Offshore Denmark With Enzymatic Calcium Carbonate Scale European Sand Management Forum 2014, 6. 61. Tibbles, R., Fracturing for Sand Control: How Hydraulic Fracturing has Changed Sand Control Society of Petroleum Engineers - Distinguished Lecturer Program 2010. 62. Focus Technology Co Ltd, Huadong High Quality Longitudinal Direction Slotted Casing for Oil Well Drilling. In Focus Technology Co., Ltd: 2018. 63. Wang, J., Perforated /Slotted Casing and Tubing. In King Well: 2017. 64. Ltd., M. W. M. P. C., Wire Wrapped Screen In MAIXIN Wire Mesh Products Co., Ltd.: 2014. 65. van Beek, K.; Breedveld, R., Cause and prevention of well bore clogging by particles Hydrogeology Journal 2009, 17, 1877-1886. 66. Law, D.; Dundas, A. S.; Reid, D. J., HPHT Horizontal Sand Control Completion Society of Petroleum Engineers 2000. 67. Sinclair, R., An Effective Method of Sand Control Proceedings - SPE Symposium on Formation Damage Control 1978, 3, 7. 68. Harter, T., Water Well Design and Construction In Service, N. R. C., Ed. Natural Resources Conservation Services: UC Davis, 2003. 69. American; Petroleum; Institute Offshore Sand Control and Well Stimulation Technology 2015.
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73
APPENDIX
SUPPLEMENTAL INFORMATION FOR CHAPTER 2
74 Table A.1. Summary of conductivity correlation equations where x is the experimental conductivity [µS*cm-1] and y is the experimental urea concentration [g*L-1].
The series-parallel inactivation scheme is described with a biexponential model
(Equation A), following one of two paths towards the irreversibly denatured enzyme, Ed.
Inactivation can occur either through the immediate inactivation of the native enzyme E or
through a series-type inactivation, with an intermediate isomer E1 (See Table 1 for more
information). The kinetic coefficient k1 represents the inactivation coefficient of
isomerization from the native form E to the active intermediate E1. While k2 represents the
coefficient of inactivation to the denatured enzyme Ed, with an activity of zero. The kinetic
coefficient k3 represents the most direct path of inactivation where the native enzyme E
follows to the completely inactivated form Ed. Finally, the coefficient β represents the ratio
of specific activities of E1*E0-1.51
1 Equation A
At 20°C, β = 1, which implies that a minor rearrangement of the enzyme results in
E1 with the same specific activity as E.51 It may be that the unfolding of the structure of
Temp (°C) Correlation Equation R2
20 y = -1.36x + 27.97 0.9830 y = -1.55x + 32.63 0.9640 y = -1.66x + 36.73 0.9650 y = -1.58x + 38.86 0.9955 y = -1.62x + 38.95 0.9460 y = -2.04x + 44.63 0.9865 y = -2.04x + 41.19 0.9470 y = -1.98x + 49.05 0.9775 y = -2.19x + 45.01 0.8380 y = -1.76x + 41.50 0.89
75 urease would present an intermediate form of the enzyme with increasingly less activity
as the enzyme denatures at higher temperatures.
This series-type inactivation scheme is a simplified version of the series-parallel
inactivation scheme. It contains the same active intermediate pathway but does not include
the direct inactivation pathway. (Equation B) (See Table 1 for more information).
1 Equation B
Figure A.1. Temperature dependent inactivation coefficient determined by plotting kd values obtained from fitting experimental data from enzyme inactivation experiments using a first-order inactivation model across the temperature range of 50-80°C
kd (T)= (2.17*1025)*exp(‐178.75*(R*T)‐1)R² = 0.99
0
0.02
0.04
0.06
0.08
0.1
0.12
320 325 330 335 340 345 350 355
k d [m
in-1
]
Temperature [kelvin]
76
Figure A.2. Apparent first-order rate coefficients [min-1] (for the first hour) determined by linear regression, fitting the first order rate expression to experimental data. Rate coefficients for JBM, SB, PP and CS are plotted for 30°C and 60°C and compared against each other (does not account for inactivation).
0
0.005
0.01
0.015
0.02
0.025
0 10 20 30 40 50 60 70 80
K urea[m
in‐1]
Temperature [°C]
First‐Order Rate Coefficient for First Hour
Jackbean Soy Pigeonpea Cottonseed
77 Table A.2. Summary of enzyme activities and ureolysis rates for plant-based sources (JBM, SB, PP, CS) of urease between 20 and 80°C. * no significant decrease in urea concentration was detected over a period of 60 minutes. ** indicates that urease became inactivated prior to hydrolyzing 95% of urea at these temperatures; apparent time of complete inactivation was 75 min at 70°C, 60 min at 75°C, and 45 min at 80°C.
Source of
ground urease
Temperature (°C)
≥ 95% Urea hydrolyzed
(min)
Activity (µmol urea
hydrolyzed/g ground
urease/ min)
Apparent kurea (min-1)
JBM 20 480 591 0.0008 JBM 30 300 970 0.0017 SB 30 > 1440 234 0.0007 PP 30 > 1440 99 0.0003 CS 30 > 1440 * *
JBM 40 180 1703 0.0026 JBM 50 120 1958 0.0055 JBM 55 105 2183 0.0052 JBM 60 60 2441 0.0081 SB 60 > 1440 839 0.0028 PP 60 > 1440 370 0.0012 CS 60 > 1440 71 0.0003
JBM 65 120 2026 0.0072 JBM 70 ** 2145 0.0087 JBM 75 ** 1543 0.0085 JBM 80 ** 1084 0.0134
78 Table A.3. Linear regression fitting was used to determine the slope which corresponds to the kd value for each temperature as summarized, along with R2 values for each inactivation line. Half-life represents the time in minutes for half of the enzyme to expire and the respective temperature.
Figure A.3. Residual ureolytic activity of jack bean meal after exposure to temperatures between 50 and 80°C for various times. The main figure displays the results out to 10,800 minutes (7.5 days), the inset allows a more detailed view of the first 720 minutes (0.5 days).
0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1
0 1200 2400 3600 4800 6000 7200 8400 9600 10800
Res
idua
l Act
ivit
y
Exposure Time [Minutes]
50°C 55°C 60°C 65°C 70°C 75°C 80°C
0
0.2
0.4
0.6
0.8
1
0 120 240 360 480 600 720
Res
idua
l Act
ivity
Exposure Time [Minutes]
79 Table A.4. Kinetic model coefficients obtained for first order, series-parallel and series-type models and their correlation coefficients from the urea consumption data [min-1]. Values for β were not shown for the series-type and series parallel models because they were assumed to be 1 for the entire temperature range.
Figure A.4. Temperature dependent inactivation coefficient for Series inactivation determined by plotting k1 values obtained from inactivation experiments across the temperature range of 50-80°C.
k1 = (3.39E‐08)e(0.18*T)
R² = 0.98
0.000.020.040.060.080.100.120.14
50 55 60 65 70 75 80
k 1[1*m
in‐1]
Temperature [C]
Series Inactivation ‐ k1
80
Figure A.5. Temperature dependent inactivation coefficient for Series inactivation determined by plotting k2 values obtained from inactivation experiments across the temperature range of 50-80°C.
Figure A.6. Temperature dependent inactivation coefficient for Series inactivation determined by plotting β values obtained from inactivation experiments across the temperature range of 50-80°C.
k2 = (2.08)*e(-0.026*T)
R² = 0.270.00
0.10
0.20
0.30
0.40
0.50
0.60
0.70
50 55 60 65 70 75 80
k 2[1
*min
-1]
Temperature [° C]
Series Inactivation - k2
y = ‐0.0241x + 1.9576R² = 0.9475
0.00
0.20
0.40
0.60
0.80
1.00
50 55 60 65 70 75 80
β(unitless)
Temperature [°C]
SeriesInactivation‐ β
81
Figure A.7. Temperature dependent inactivation coefficient for Series-parallel inactivation determined by plotting k1 values obtained from inactivation experiments across the temperature range of 50-80°C.
Figure A.8. Temperature dependent inactivation coefficient for Series-parallel inactivation determined by plotting k2 values obtained from inactivation experiments across the temperature range of 50-80°C.
k1 = 4.10E‐09e(0.12*T)
R² = 0.27
0.0000
0.0005
0.0010
0.0015
50 55 60 65 70 75 80
k 1[1*m
in‐1]
Temperature [°C]
SeriesParallelInactivation‐ k1
k2 = 1.80E‐03e(0.03*T)
R² = 0.03
0.0000
0.0200
0.0400
0.0600
0.0800
50 55 60 65 70 75 80
k 2 [1*m
in‐1]
Temperature [deg C]
SeriesParallelInactivation‐ k2
82
Figure A.9. Temperature dependent inactivation coefficient for Series-parallel inactivation determined by plotting k3 values obtained from inactivation experiments across the temperature range of 50-80°C.
Figure A.10. Temperature dependent inactivation coefficient for Series-parallel inactivation determined by plotting β values obtained from inactivation experiments across the temperature range of 50-80°C.
k3 = 3.54E‐08e(0.18*T)
R² = 0.98
0.00
0.02
0.04
0.06
0.08
0.10
0.12
50 55 60 65 70 75 80
k 3[1*m
in‐1]
Temperature [deg C]
SeriesParallelInactivation‐ k3
y = ‐0.0119x + 1.1572R² = 0.8837
0
0.2
0.4
0.6
0.8
1
20 30 40 50 60 70 80
β (unitless)
Temperature [°C]
SeriesParallelInactivation‐ β
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